RU2579994C2 - Active decoys against radar sources and method for protecting objects using said decoys - Google Patents

Abstract

FIELD: radio engineering and communications.

SUBSTANCE: invention relates to microwave engineering and is intended for active noise setting devices, which are used to deflect include system equipped with radar station. Device provides formation of corresponding clouds using active interference installation devices containing at least one antenna, one receiver, one signal processing device and one radio transmitter, one power supply, as well as system on one chip SoC system in case of SIP and integrated circuit of special purpose ASIC with integrated receiving-transmitting unit. Antenna is antenna with very wide frequency range.

EFFECT: high degree of protection of objects.

16 cl, 6 dwg

Description

The invention relates to active jamming devices (dipole reflectors, etc.), especially miniature ones, which are used to deflect an approaching system equipped with a radar station, such as a projectile, a rocket, etc., and other unmanned aerial vehicles from the protected object, and which, therefore, must deceive this system. Such jamming devices can preferably be made without ammunition and, moreover, can be used in civilian areas.

Various countermeasures are known to protect objects such as ships, planes and land vehicles, as well as non-mobile objects.

The first countermeasure is, for example, firing so-called dipole reflectors from metallized fibers, such as staniol, and the formation of a cloud that has a larger radar scattering area than the original target (US 6876320 A; US 2008/0198060 A; US 2009/02511353 A )

Another option is to shoot down guided missiles that receive and analyze a radar signal and send a false signal (US 5388783 A; US 6628239 A; US 2009/0189799 A).

In addition, guided missiles are emitted that reflect the incoming signal, for example, as a radar beacon or Van Atta antenna array (US 3,496,570 A; US 3,731,313 A; US 3,938,151 A).

Direct measures are also known, for example, such as firing such unmanned aerial vehicles with weapons systems such as automatic guns, and launching guided missiles - air defense - against this kind of danger.

When using remote active electronic jamming stations, the incoming radar signal is received and analyzed. After that, a false signal is sent (US 3258771 A; US 3896438 A; US 3958241 A; US 4126862 A; US 4646098 A).

Another possibility is to use the invisible cap technology. At the same time, absorbent materials are applied to the surface, in particular of mobile objects, in accordance with the technology of applying thick layers or composite materials. In this case, isotropic media and dielectrics are known made by extrusion or from foamed plastics, graphites, etc. (US 4606848 A), magnetic absorbent substances and anisotropic media (ferrites) (US 3662387 A) or bianisotropic, chiral absorbent substances (US 4606848 A), etc.

A disadvantage of the known devices is that the known active jamming devices, as a rule, consist of a separate receiving and transmitting unit as a payload and need a power source.

A system for protecting ships is known from DE 10346001 B4, which is responsible for ejecting such effective elements or dipole reflectors.

From DE 10 2006 017 107 A, a variant is known in which such effective elements are fired at an object and irradiated by the object itself or another radar station. Thus, a cloud is formed for the homing head, which is characterized by an increased frequency of reflectors, so that this head switches to this cloud. Such dipole reflectors are called active jamming devices.

The objective of the invention is to provide an active device for the installation of interference, with which in a simple form provides an effective impact on a flying object.

This problem is solved by the features of paragraph 1 of the claims, as well as paragraph 6 of the claims. Advantageous forms of carrying out the invention are given in the dependent clauses.

The basis of the invention is the idea for the formation of the corresponding cloud using active jamming devices, it is preferable to print an antenna on each such device, as well as the so-called single-chip system (SoC), system in the case (SiP) or special purpose integrated circuit (ASIC) with integrated receiving and transmitting unit. The size of the design with an RFID (radio frequency identification) device is approximately the size of a chip card. If necessary, an appropriate power source based on a film or other can be integrated. An antenna with a very wide frequency range should preferably be used as an antenna.

This kind of miniature design allows you to shoot hundreds of such active jamming devices or use them as the payload of the carrier.

Another advantage is that the jamming devices can be placed in a cloud with different radar scattering areas, so that a wide range with variable parameters can be covered as protective measures. Since individual jamming devices are small and used in large numbers, you can even reproduce the corresponding silhouette of the protected object. In addition, a plane in front of the protected object can be created from the jamming devices.

An approaching guided missile sends only one radar signal to navigate and control its flight path. Each of the jamming devices located in the cloud receives this signal, evaluates it in SoC or ASIC and sends the corresponding, in this case, partially modified amplified false signal (back). It is also possible to emit Doppler frequencies during fast relative motions or also other modulated waveforms by SoC, SiP or ASIC. Using a modification, you can, for example, simulate speed. Sent signals are received by the aircraft radar and are regarded as a useful signal (large radar scattering area when a cloud forms).

Pulse firing and acceleration of active jamming devices can be carried out, among other things, by throwing grenades, ammunition, guided projectiles or effective elements that fire active jamming devices in a certain way. However, firing of active jamming devices can also be realized with the help of intermediate accumulated compressed gas or with the help of long-term firing with the help of blowers, pumps, compressors, etc. You can also use the spring tension forces - catapults, arcs, etc. - or rail (electromagnetic) guns (shock electromagnetic conversion of accumulated electrical energy) to distribute active jamming devices. Combinations of the above options are possible.

Thus, the advantage is that these active jamming devices can be used flexibly in comparison with radar recognition, which makes it possible to additionally equip the protected objects in a simple way, i.e. use existing firing mechanisms without resorting to costly upgrades and installation.

The invention is explained in more detail using the figures of the drawings with reference to an example implementation. Shown:

Figure 1 the principle of the active device for the installation of interference (radar-producer simulation interference),

FIG. 2 is a schematic illustration of an active jamming device,

FIG. 3 image of a cloud from several active jamming devices,

FIG. 4a-c image of a cloud in applications for protecting various objects.

Figure 1 shows a schematic diagram of the so-called radar director 1 radar jamming, which presents: a receiver 2, a device 3 for processing signals (amplifier-V), a radio transmitter 4 and a diplexer 5.

The input signal R of the radar radiation source - here the radar guidance head 10 (Fig. 4) - is received by the receiver 2 using the antenna 6 and enters the device 3 for processing the signal. The signal processing device 3 analyzes this signal and, depending on the type of simulation, transmits a special signal R 'to the radio transmitter 4. Then this signal is returned again via the antenna 7 to the radar radiation source 10. It is preferable to use a common antenna 7, which should be connected to the corresponding unit 2, 4 through a diplexer 8. Installation with two or more separate antennas is also possible.

There are several possibilities for signal processing and transmission. Four examples are given here as an example.

The first possibility is to increase the radar scattering area for continuous and pulsed radars. In this case, the input signal R is amplified linearly and without distortion.

The second possibility is the delay of the radar signal, the input signal R being returned to the source 10 with delay, so that the reflected signal later arrives at this source 10 of the radar radiation. Thus, the target appears at a greater distance.

A third possibility is to generate a Doppler frequency at the Doppler radar. Given the input signal and the speed of the radar transmitter 10 and target 11, the Doppler frequency is calculated in the device 3 for processing signals and transmitted. This method can be used if the simulation system (not shown here in detail) meets the required parameters.

An alternative, fourth possibility is a combination of the above possibilities.

Figure 2 shows a diagram of a preferred connection radar director 1 simulation interference on the substrate 1 ', for example, from paper or synthetic film. The dipole-shaped antenna 7 is mounted on the substrate (s) 1 ′. All electronic components of the device 1 installation of interference are powered by a power source 8. As the power source 8, a chemical, solar, or similar battery may be used.

Figure 3 shows the cloud 12, which is formed by devices 1 installation interference / radar-director of simulation interference.

4a-c show protection options. In Fig. (A), a simulation signal R 'is generated by the formation of a cloud 12 behind the ship 11.1. In Fig. (B) it is shown how the protection of the land vehicle 11.2 is carried out, and in Fig. (C) - of the aircraft 11.3. The protection of an immovable property / building, which may also apply, is not presented in more detail.

Claims (16)

1. The active device (1) installation of interference, acting against sources (10) of radar radiation, containing at least one antenna (6, 7), one receiver (2), one device (3) for signal processing and one radio transmitter ( 4), as well as one power source (8), the antenna (6, 7) connected to the receiver (2), the receiver (2) to the signal processing device (3), the signal processing device (3) with the antenna (6, 7) ), characterized in that the antenna (6, 7) is printed on the jamming device (1), as well as a system on a single SoC chip, a system in the SiP package, and an integrated circuit and a special purpose ASIC with an integrated transmit-receive unit (2, 4). 2. The device (1) according to claim 1, characterized in that the antenna (6, 7) is made in the form of a dipole, which can be switched on as a receiving antenna (6) or as a transmitting antenna (7). 3. The device (1) according to claim 1, characterized in that the jamming device (1) has at least one, preferably several, substrates (1 ′) of paper or synthetic film. 4. The device (1) according to claim 2, characterized in that the antenna (6, 7) in the form of a dipole is mounted on a separate substrate (1) or on the substrates (1). 5. The device (1) according to claim 1, characterized in that a chemical or solar battery is used as a power source. 6. The device (1) according to any one of paragraphs. 1-5, characterized in that the antenna (6, 7) uses an antenna with a very wide frequency range. 7. The device (1) according to claim 1, characterized in that the device (1) for jamming is placed in a cloud (9) with different radar scattering area. 8. A method of deceiving a radar radiation source (10) to protect an object (11) by means of a jamming device (1) according to any one of paragraphs. 1-7, characterized in that the following steps are performed:
- firing device (1) installation of interference,
- cloud formation (12),
- receiving the input signal (R) sent by the radar source (10) to the jamming device (1),
- signal processing (R) in the device (3) for processing signals,
- transmitting the reflected signal (R ′) back to the radar radiation source (10). 9. The method according to p. 8, characterized in that the antenna (6, 7) is connected to the corresponding receiver (2), the radio transmitter (4) through a diplexer. 10. The method according to p. 8, characterized in that the input signal (R) is transmitted back in the form of a reflected signal (R ′), amplified linearly and without distortion, and an increase in the radar scattering area for continuous and pulsed radars is performed. 11. The method according to p. 8, characterized in that the input signal (R) is returned to the source (10) with delay, so that the reflected signal later arrives at this radiation source of the radar (10), and thereby the target appears at a greater distance. 12. The method according to p. 8, characterized in that the Doppler frequency is determined and transmitted in the device (3) for signal processing. 13. The method according to any one of paragraphs. 8-12, characterized in that they use other forms of modulation, such as FM, PM, AM, which are detected and transmitted. 14. The method according to p. 12 or 13, characterized in a combination of paragraphs. 15. The use of the device (1) installation of interference according to any one of paragraphs. 1-7 to protect the ship 11.1, vehicle 11.2, aircraft 11.3, as well as an immovable object / building. 16. Ammunition with the device (1) installation of interference according to any one of paragraphs. 1-7.

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